CN102515550B - Near-infrared quantum-cutting down-conversion luminescent transparent glass ceramic and preparation method thereof - Google Patents
Near-infrared quantum-cutting down-conversion luminescent transparent glass ceramic and preparation method thereof Download PDFInfo
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- CN102515550B CN102515550B CN201110403128.9A CN201110403128A CN102515550B CN 102515550 B CN102515550 B CN 102515550B CN 201110403128 A CN201110403128 A CN 201110403128A CN 102515550 B CN102515550 B CN 102515550B
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Abstract
The present invention discloses a kind of near-infrared quantum-cutting down-conversion luminescent transparent glass ceramic.The component of glass-ceramic and molar content are SiO
2: 30-50mol%; Al
2o
3: 20-35mol%; CaCO
3: 5-20mol%; NaF:5-20mol%; CaF
2: 9.6-14.5mol%; EuF
3: 0.1-1.0mol%; YbF
3: 0-2mol%.Sample adopts melt supercooled method and subsequent heat treatment preparation, and method is simple, pollution-free and cost is low.This transparent glass ceramics and silicon solar cell are coupled, are expected to the thermo effect reducing silicon solar cell, improve the photoelectric transformation efficiency of battery.
Description
Technical field
The present invention relates to solid luminescent material field, especially relate to a kind of can the rare earth doping transparent glass-ceramic of near-infrared quantum-cutting down-conversion luminescent of broadband excitation and preparation technology thereof.
Technical background
The world today, traditional fossil energy is just petered out, and the mankind are in the urgent need to development and application new forms of energy.Sun power is primary energy source, is again renewable energy source, the new energy technology utilizing silicon solar cell photovoltaic generation to become each developed country competitively to develop.At present, the photoelectric transformation efficiency of common on market single crystal silicon solar cell is about 15-18%; According to calculating, band gap is that the theoretical efficiency of the single p-n junction silicon solar cell of 1.1eV is also no more than 30%.This is because solar spectrum does not mate with single crystal silicon semiconductor spectral response, thus produces infrared energy loss and dot matrix thermalization energy loss causes.Modulating solar spectrum by conversion regime under quantum-cutting is a kind of feasible method making silicon solar cell energy efficiency surmount 30%, and it relates to the two-phonon process that a high-energy photon is converted to multiple lower energy photon simultaneously.If an incident ultraviolet-visible photon can be converted to two near infrared photons, so the dot matrix thermalization power loss of solar cell will significantly reduce.Because level structure is enriched, rare earth ion can absorb or launch from ultraviolet to the electromagnetic radiation can seeing the various wavelength in infrared region, is expected to realize effective quantum-cutting down-conversion luminescent.In recent years, the combination (as: Tb of some rare earth ions
3+/ Yb
3+, Tm
3+/ Yb
3+, Pr
3+/ Yb
3+) be widely studied for changing under quantum-cutting optical frequency.But because the 4f-4f transition of group of the lanthanides trivalent rare earth is parity forbidden, its absorption intensity is more weak, this makes it be difficult to utilize sunlight efficiently.Due to Ce
3+and Eu
2+4f-5d transition be parity allow, in solar spectrum region, there is very strong receptivity, therefore, based on Ce
3+/ Yb
3+or Eu
2+/ Yb
3+under the quantum-cutting of rare earth ion combination, transition material causes the concern of people gradually.Our seminar reports Ce in borate glass
3+/ Yb
3+quantum-cutting down-conversion luminescent [J.Appl.Phys., 104,116105 (2008)], Zhou etc. report Eu equally in borate glass subsequently
2+/ Yb
3+quantum-cutting down-conversion luminescent [Appl.Phys.Lett., 95,141101 (2009)].It is generally acknowledged, from Ce
3+or Eu
2+to Yb
3+energy transfer process be the common cooperation energy transfer process that energy is passed to two acceptor ions by a donor ion simultaneously.
Transparent oxyfluoride glass ceramic is the suitable matrix realizing rare earth ion quantum-cutting down-conversion luminescent.After rare earth ion to enter the fluoride nano crystal crystallographic site that crystallization separates out in the mode of replacing solid solution, change probability under the transmission ofenergy between them and the shortening due to phase mutual edge distance is increased; Meanwhile, the feature of fluoride nano crystal low phonon energy environment also contributes to realizing efficient quantum-cutting down-conversion luminescent.
The present invention has utilized melt supercooled legal system standby containing Eu
2+/ Yb
3+: CaF
2nanocrystalline transparent glass ceramics.Eu
2+can within the scope of 250 nanometer-375 nano wavebands wide band absorption UV-light, and by the mode of altogether cooperation transmission ofenergy, a ultraviolet photon is converted to two near infrared photons.Be combined with solar cell because transparent inorganic glass pottery can substitute traditional packaged glass, this material has significant application value in reduction silicon solar cell thermo effect, raising photoelectric transformation efficiency.
Summary of the invention
The present invention proposes a kind of Eu
2+/ Yb
3+the component of the transparent glass ceramics mixed altogether and preparation technology thereof, object is to prepare Stability Analysis of Structures, having can the transparent solid luminescent material of near-infrared quantum-cutting down-conversion luminescent characteristic of broadband excitation.
Component and the molar content of transparent glass ceramics of the present invention are as follows:
SiO
2: 30-50mol%; Al
2o
3: 20-35mol%; CaCO
3: 5-20mol%; NaF:5-20mol%; CaF
2: 9.6-14.5mol%; EuF
3: 0.1-1.0mol%; YbF
3: 0-2mol% (above-mentioned each component concentration sum is 100mol%).
Technical scheme of the present invention is as follows:
Various powder raw material is weighed according to certain component proportion, mixing and grinding is placed in crucible, put into resistance furnace be heated to 1300 ~ 1400 DEG C after insulation within 1 ~ 3 hour, make it melting, then, by liquation take out and pouring into fast in copper mold be shaped obtain forerunner's glass; Forerunner's glass is put into resistance furnace and anneal 2 hours to eliminate internal stress in 430 DEG C.At 590 DEG C, 6 hours isothermal processes are carried out to above-mentioned glass, makes it generating portion crystallization, just obtain transparent glass ceramics.
The crucible used in preparation process can be platinum crucible or corundum crucible.
Powder X-ray diffraction analysis shows, in the transparent glass ceramics utilizing aforesaid method to prepare, crystallization separates out single Emission in Cubic CaF
2nanocrystalline; Transmission electron microscope observation shows, average dimension is the CaF of 10 nanometers
2nanocrystallinely to be embedded in equably in unorganic glass matrix.Fluorescence spectrophotometer measurement shows, uses ultraviolet excitation Eu
2+, can be observed Yb
3+:
2f
5/2→
2f
7/2the quantum-cutting near infrared light emission band (centre wavelength is 980 nanometers) of transition.By optimizing material component and rear-earth-doped concentration, the theoretical internal quantum efficiency of transparent glass ceramics quantum-cutting down-conversion luminescent can reach 151%.
Transparent glass ceramics preparation technology of the present invention is simple, with low cost, nontoxic pollution-free, there is good mechanical property and thermal stability, be expected to develop become a kind of can the near-infrared quantum-cutting down-conversion luminescent material of broadband excitation, have broad application prospects in solar cell field.
Accompanying drawing explanation
Fig. 1 is the X-ray diffractogram of glass-ceramic sample in example 1;
Fig. 2 is the transmission electron microscope bright field image of glass-ceramic sample in example 1;
Fig. 3 is the excitation spectrum of glass-ceramic sample in example 1;
Fig. 4 is the emission spectrum of glass-ceramic sample in example 1;
Fig. 5 is Eu in example 1
2+: the fluorescence decay curve of 5d → 4f transition;
Fig. 6 is Eu
2+/ Yb
3+switching mechanism schematic diagram under cooperation transmission ofenergy altogether.
Embodiment
Example 1: by analytically pure SiO
2, Al
2o
3, CaCO
3, NaF, CaF
2be the EuF of 99.99% with purity
3, YbF
3powder, by 45SiO
2-25Al
2o
3-5CaCO
3-10NaF-12.5CaF
2-0.5EuF
3-2YbF
3proportioning accurate weighing be placed in agate mortar, grinding more than half an hour makes it Homogeneous phase mixing, and be placed in platinum crucible, be heated to 1350 DEG C in program control high temperature box type resistance furnace after, insulation makes it melting in 2 hours, then, liquation taken out and pours cooling forming in copper mold fast into, obtaining forerunner's glass; Forerunner's glass is put into resistance furnace, and after annealing 2 hours at 430 DEG C, furnace cooling is to eliminate internal stress.Glass after annealing is made it generating portion crystallization in 6 hours 590 DEG C of insulations, obtains transparent glass ceramics.
Powder X-ray diffractogram (Fig. 1) analysis shows, the crystalline phase separated out in unorganic glass matrix is single CaF
2emission in Cubic; Transmission electron microscope observation shows, average dimension is the CaF of 10 nanometers
2uniform crystal particles is distributed in (as shown in Figure 2) among glass basis; Sample, through surface finish, carries out light at room temperature spectrometry by FLS920 fluorescence spectrophotometer, observes typical Eu
2+: broadband (250 nanometer-375 nanometer) excitation peak (as shown in Figure 3) of 4f → 5d transition, Eu
2+: the broadband emission peak of 5d → 4f transition and Yb
3+:
2f
5/2→
2f
7/2the quantum-cutting near infrared light emission band (centre wavelength is 980 nanometers) (as shown in Figure 4) of transition.According to Eu
2+: the fluorescence decay curve (as shown in Figure 5) of 5d → 4f transition, calculating total light yield is most effective reaches 151%.Fig. 6 is Eu
2+/ Yb
3+altogether switching mechanism schematic diagram under cooperation transmission ofenergy, when an incident ultraviolet photon is by Eu
2+after absorption, Eu
2+ion generation Stokes shift sends blue light; On the other hand, because blue light energy is close to Yb
3+2 times of ion near infrared energy, therefore Eu
2+transmission ofenergy can be given the Yb of two neighbours by ion simultaneously
3+ion, thus realize Yb
3+switching emission under the near-infrared quantum-cutting of ion.
Example 2: by analytically pure SiO
2, Al
2o
3, CaCO
3, NaF, CaF
2be the EuF of 99.99% with purity
3, YbF
3powder, by 30SiO
2-35Al
2o
3-10CaCO
3-15NaF-8CaF
2-1EuF
3-1YbF
3proportioning accurate weighing be placed in agate mortar, grinding more than half an hour makes it Homogeneous phase mixing, and be placed in platinum crucible, be heated to 1300 DEG C in program control high temperature box type resistance furnace after, insulation makes it melting in 1 hour, then, liquation taken out and pours cooling forming in copper mold fast into, obtaining forerunner's glass; Forerunner's glass is put into resistance furnace, and after annealing 2 hours at 430 DEG C, furnace cooling is to eliminate internal stress.Glass after annealing is made it generating portion crystallization in 6 hours 590 DEG C of insulations, obtains transparent glass ceramics.Sample, through surface finish, carries out light at room temperature spectrometry by FLS920 fluorescence spectrophotometer, observes typical Eu
2+: broadband (250 nanometer-375 nanometer) excitation peak of 4f → 5d transition, and correspond to Yb
3+:
2f
5/2→
2f
7/2the quantum-cutting near infrared light emission band (centre wavelength is 980 nanometers) of transition.
Example 3: by analytically pure SiO
2, Al
2o
3, CaCO
3, NaF, CaF
2be the EuF of 99.99% with purity
3, YbF
3powder, by 50SiO
2-20Al
2o
3-10CaCO
3-5NaF-14.4CaF
2-0.1EuF
3-0.5YbF
3proportioning accurate weighing be placed in agate mortar, grinding more than half an hour makes it Homogeneous phase mixing, and be placed in platinum crucible, be heated to 1400 DEG C in program control high temperature box type resistance furnace after, insulation makes it melting in 3 hours, then, liquation taken out and pours cooling forming in copper mold fast into, obtaining forerunner's glass; Forerunner's glass is put into resistance furnace, and after annealing 2 hours at 430 DEG C, furnace cooling is to eliminate internal stress.Glass after annealing is made it generating portion crystallization in 6 hours 590 DEG C of insulations, obtains transparent glass ceramics.Sample, through surface finish, carries out light at room temperature spectrometry by FLS920 fluorescence spectrophotometer, observes typical Eu
2+: broadband (250 nanometer-375 nanometer) excitation peak of 4f → 5d transition, and correspond to Yb
3+:
2f
5/2→
2f
7/2the quantum-cutting near infrared light emission band (centre wavelength is 980 nanometers) of transition.
Example 4: by analytically pure SiO
2, Al
2o
3, CaCO
3, NaF, CaF
2be the EuF of 99.99% with purity
3, YbF
3powder, by 35SiO
2-30Al
2o
3-15CaCO
3-10NaF-9.6CaF
2-0.2EuF
3-0.2YbF
3proportioning accurate weighing be placed in agate mortar, grinding more than half an hour makes it Homogeneous phase mixing, and be placed in platinum crucible, be heated to 1350 DEG C in program control high temperature box type resistance furnace after, insulation makes it melting in 2 hours, then, liquation taken out and pours cooling forming in copper mold fast into, obtaining forerunner's glass; Forerunner's glass is put into resistance furnace, and after annealing 2 hours at 430 DEG C, furnace cooling is to eliminate internal stress.Glass after annealing is made it generating portion crystallization in 6 hours 590 DEG C of insulations, obtains transparent glass ceramics.Sample, through surface finish, carries out light at room temperature spectrometry by FLS920 fluorescence spectrophotometer, observes typical Eu
2+: broadband (250 nanometer-375 nanometer) excitation peak of 4f → 5d transition, and correspond to Yb
3+:
2f
5/2→
2f
7/2the quantum-cutting near infrared light emission band (centre wavelength is 980 nanometers) of transition.
Example 5: by analytically pure SiO
2, Al
2o
3, CaCO
3, NaF, CaF
2be the EuF of 99.99% with purity
3, YbF
3powder, by 30SiO
2-20Al
2o
3-20CaCO
3-20NaF-9.6CaF
2-0.5EuF
3-0.1YbF
3proportioning accurate weighing be placed in agate mortar, grinding more than half an hour makes it Homogeneous phase mixing, and be placed in platinum crucible, be heated to 1350 DEG C in program control high temperature box type resistance furnace after, insulation makes it melting in 2 hours, then, liquation taken out and pours cooling forming in copper mold fast into, obtaining forerunner's glass; Forerunner's glass is put into resistance furnace, and after annealing 2 hours at 430 DEG C, furnace cooling is to eliminate internal stress.Glass after annealing is made it generating portion crystallization in 6 hours 590 DEG C of insulations, obtains transparent glass ceramics.Sample, through surface finish, carries out light at room temperature spectrometry by FLS920 fluorescence spectrophotometer, observes typical Eu
2+: broadband (250 nanometer-375 nanometer) excitation peak of 4f → 5d transition, and correspond to Yb
3+:
2f
5/2→
2f
7/2the quantum-cutting near infrared light emission band (centre wavelength is 980 nanometers) of transition.
Claims (3)
1. have a near-infrared quantum-cutting down-conversion luminescent transparent glass ceramic, its feed composition and molar content are SiO
2: 30-50mol%; Al
2o
3: 20-35mol%; CaCO
3: 5-20mol%; NaF:5-20mol%; CaF
2: 9.6-14.5mol%; EuF
3: 0.1-1.0mol%; YbF
3: 0-2mol%.
2. transparent glass ceramics according to claim 1, is characterized in that: the Calcium Fluoride (Fluorspan) being uniformly distributed cubic structure in the glass basis of this transparent glass ceramics is nanocrystalline, and crystal grain average dimension is 10 nanometers, the rare earth ion of doping be gathered in Calcium Fluoride (Fluorspan) nanocrystalline in.
3. the preparation method of the glass-ceramic of a claim 1, it is characterized in that: raw material is weighed according to feed composition proportioning according to claim 1, mixing and grinding is placed in crucible, put into resistance furnace be heated to 1300 ~ 1400 DEG C after insulation within 1 ~ 3 hour, make it melting, then, liquation taking-up also poured fast into shaping in copper mold and obtaining forerunner's glass; Forerunner's glass is put into resistance furnace and anneal 2 hours to eliminate internal stress in 430 DEG C, finally, carry out 6 hours Isothermal treatment at 590 DEG C, make it generating portion crystallization.
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| CN1955130A (en) * | 2005-10-24 | 2007-05-02 | 中国科学院福建物质结构研究所 | Glass ceramic and its preparation method |
| CN101088946A (en) * | 2006-06-13 | 2007-12-19 | 中国科学院福建物质结构研究所 | Er-doped transparent glass ceramics containing nanometer sodium yttrium fluoride crystal and its prepn and use |
| CN101209898A (en) * | 2006-12-27 | 2008-07-02 | 中国科学院福建物质结构研究所 | Erbium-doped barium-yttrium-fluoride-nanocrystalline containing transparent oxyfluoride glass ceramic and preparation thereof |
| CN101353229A (en) * | 2008-09-05 | 2009-01-28 | 浙江大学 | Rare earth ion doped down-conversion luminescent transparent glass-ceramics |
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| CN1955130A (en) * | 2005-10-24 | 2007-05-02 | 中国科学院福建物质结构研究所 | Glass ceramic and its preparation method |
| CN101088946A (en) * | 2006-06-13 | 2007-12-19 | 中国科学院福建物质结构研究所 | Er-doped transparent glass ceramics containing nanometer sodium yttrium fluoride crystal and its prepn and use |
| CN101209898A (en) * | 2006-12-27 | 2008-07-02 | 中国科学院福建物质结构研究所 | Erbium-doped barium-yttrium-fluoride-nanocrystalline containing transparent oxyfluoride glass ceramic and preparation thereof |
| CN101353229A (en) * | 2008-09-05 | 2009-01-28 | 浙江大学 | Rare earth ion doped down-conversion luminescent transparent glass-ceramics |
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| 基于稀土离子间能量传递的宽带下转换光谱调制的研究进展;周佳佳等;《硅酸盐学报》;20110430;第39卷(第4期);第619-621页 * |
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